Flexible ethernet and multi link gearbox mapping procedure to optical transport network

1. A flexible mapping method, implemented in circuitry, to map a Physical Coding Sublayer (PCS) structure from one of Flexible Ethernet and Multi Link Gearbox (MLG) to Optical Transport Network (OTN), the flexible mapping method comprising: receiving one or more Virtual Lanes from the one of Flexible Ethernet and MLG; mapping each of the one or more Virtual Lanes into an associated Tributary Slot utilizing a Bit-synchronous Mapping Procedure (BMP) in an Optical channel Payload Unit flex (OPUflex) that is mapped into an Optical channel Data Unit flex (ODUflex) in OTN, wherein a Payload Type (PT) is defined in the OPUflex with a rate and number of the Tributary Slots set based on a rate and number of the one or more Virtual Lanes, wherein the Tributary Slots have a rate comparable to a rate of the one or more Virtual Lanes; and utilizing Remote Management (RM) channels or specific Alignment Markers (AM) to communicate a status of the one or more Virtual Lanes in the corresponding Tributary Slots between a router and transport equipment containing the circuitry, wherein the status includes an unused or Open Connection Indication (OCI)) for each of the one or more Virtual Lanes, and the status is communicated from one of the router and the transport equipment to the other, wherein the Virtual Lane is one of about 5 Gb/s and about 25 Gb/s, and wherein the Payload Type (PT) is defined in OTN designating a Tributary Slot of one of about 5 Gb/s and about 25 Gb/s based on a size of the Virtual Lane.

2. The flexible mapping method of claim 1 , further comprising: resizing the ODUflex responsive to a change in a number of the one or more Virtual Lanes.

3. The flexible mapping method of claim 1 , further comprising: mapping the associated Tributary Slots into the Optical channel Data Unit flex (ODUflex); and performing one of providing the ODUflex to an OTN switch, mapping the ODUflex into an Optical channel Transport Unit k (k=0, 1, 2, 3, 4, flex) or C=100×n (n=1, 2, 3, . . . ) (OTUk/Cn), or aggregating the ODUflex with other signals in the OTUk/Cn.

4. A transport system configured to map a Physical Coding Sublayer (PCS) from one of Flexible Ethernet and Multi Link Gearbox (MLG) to Optical Transport Network (OTN), the transport system comprising: circuitry configured to receive one or more Virtual Lanes from the one of Flexible Ethernet and MLG; circuitry to map each of the one or more Virtual Lanes into an associated Tributary Slot utilizing a Bit-synchronous Mapping Procedure (BMP) in an Optical channel Payload Unit flex (OPUflex) that is mapped into an Optical channel Data Unit flex (ODUflex) in OTN, wherein a Payload Type (PT) is defined in the OPUflex with a rate and number of the Tributary Slots set based on a rate and number of the one or more Virtual Lanes, wherein the Tributary Slots have a rate comparable to a rate of the one or more Virtual Lanes; and circuitry configured to utilize Remote Management (RM) channels or specific Alignment Markers (AM) to communicate a status of the one or more Virtual Lanes in the corresponding Tributary Slots between a router and the transport system, wherein the status includes an unused or Open Connection Indication (OCI)) for each of the one or more Virtual Lanes, and the status is communicated from one of the router and the transport equipment to the other, wherein the Virtual Lane is one of about 5 Gb/s and about 25 Gb/s, and wherein the Payload Type (PT) is defined in OTN designating a Tributary Slot of one of about 5 Gb/s and about 25 Gb/s based on a size of the Virtual Lane.

5. The transport system of claim 4 , further comprising: circuitry configured to resize the ODUflex responsive to a change in a number of the one or more Virtual Lanes.

6. The transport system of claim 4 , further comprising: circuitry configured to map the associated Tributary Slots into the Optical channel Data Unit flex (ODUflex); and circuitry configured to perform one of providing the ODUflex to an OTN switch, mapping the ODUflex into an Optical channel Transport Unit k (k=0, 1, 2, 3, 4, flex) or C=100×n (n=1, 2, 3, . . . ) (OTUk/Cn), or aggregating the ODUflex with other signals in the OTUk/Cn.

7. A flexible de-mapping method, implemented in circuitry, to de-map Optical Transport Network (OTN) with Tributary Slots to Virtual Lanes for one of Flexible Ethernet and Multi Link Gearbox (MLG), the flexible de-mapping method comprising: receiving an OTN signal with one or more Tributary Slots contained therein; de-mapping each of the one or more Tributary Slots to output a Virtual Lane for the one of Flexible Ethernet and MLG for each of the one or more Tributary Slots in an Optical channel Payload Unit flex (OPUflex) that is mapped into an Optical channel Data Unit flex (ODUflex) in utilizing a Bit-synchronous Mapping Procedure (BMP), wherein a Payload Type (PT) is defined in OTN with a rate and number of the one or more Tributary Slots set based on a rate and number of the Virtual Lane, wherein the Tributary Slots have a rate comparable to a rate of the one or more Virtual Lanes; and utilizing Remote Management (RM) channels or specific Alignment Markers (AM) to communicate a status of the one or more Virtual Lanes in the corresponding Tributary Slots between a router and transport equipment containing the circuitry, wherein the status includes an unused or Open Connection Indication (OCI)) for each of the one or more Virtual Lanes, and the status is communicated from one of the router and the transport equipment to the other, wherein the Virtual Lane is one of about 5 Gb/s and about 25 Gb/s, and wherein the Payload Type (PT) is defined in OTN designating a Tributary Slot of one of about 5 Gb/s and about 25 Gb/s based on a size of the Virtual Lane.

8. The flexible de-mapping method of claim 7 , further comprising: providing each of the Virtual Lanes to a router.